chromatography assembly for multi-dimensional chromatography, includes a first separating column (12; 112) for separating a sample into components; a second separating column (13; 114) having different separating characteristics for further separating the components separated in the first separating column (12; 112); a collecting volume (20; 120, 121) for collecting the components from the first separating column (12; 112) before entering the second separating column (14; 114); a switching assembly (22, 24; 122, 124) for switching from a first state (FIG. 1; FIG. 3), where the components leaving the first separating column (12; 112) are collected in the collecting volume (20; 120, 121) to a second state (FIG. 2; FIG. 4) where the components collected in the collecting volume (20; 120, 121) are transferred to the second separating column (14; 114); and a detector (18; 118) for detecting sample components leaving the second separating column (14; 114). The volume of the collecting volume (20; 120, 121) is variable. A further collecting volume (121) may be provided and fluid flow can be through the first collecting volume (120) in the first state and through the second collecting volume (121) in the second state.
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16. chromatography assembly for carrying out a multi-dimensional chromatography analysis of a sample, comprising
(a) a first separating column for separating said sample flowing through said separating column into components;
(b) a second separating column for further separating said components separated in said first separating column, wherein said second separating column has different separating characteristics than said first separating column;
(c) a collecting volume for collecting said components separated in said first separating column before entering said second separating column said collecting volume being arranged in a flow path between said first and said second separating column;
(d) a switching assembly for switching said chromatography assembly from a first state, where said components leaving said first separating column are collected in said collecting volume to a second state where said components collected in said collecting volume are transferred to said second separating column; and
(e) a detector for detecting sample components leaving said second separating column:
and
(f) including one or more additional collecting volumes each having a different interior size and interchangeable to become the collecting volume of section (c) wherein the interior size of said collecting volume of section (c) is variable by selecting the desired collecting volume for the collecting volume of section (c).
9. Method for generating a multi-dimensional chromatogram of a sample material comprising the steps of:
obtaining a chromatography assembly having a first separating column having first column characteristics, a second separating column having second column characteristics, and a flow path between said first separating column and said second separating column having a collecting volume receiving space therein for removably and interchangeably receiving a collecting volume in said collecting volume receiving space;
selecting operating conditions for the chromatography assembly for generating the multi-dimensional chromatogram of the sample material;
determining from one or more of the first and second column characteristics and from the selected operating conditions a desired volume of sample to be collected from the first column to then be fed to the second column;
obtaining a collecting volume having an interior size to hold a sample volume approximating the desired volume of sample to be collected;
removably and interchangably connecting the obtained sample volume in the collecting volume receiving space in the flow path between the first separating column and the second separating column;
separating the sample in the first separating column into a plurality of components;
collecting said components in the collecting volume;
separating said collected components in the second separating column; and
detecting said components separated in said second separating column;
and wherein
said collecting volume is adapted to one or more of the characteristics of said columns and operating conditions.
1. chromatography assembly for carrying out a multi-dimensional chromatography analysis of a sample, comprising
(a) a first separating column for separating said sample flowing through said separating column into components;
(b) a second separating column for further separating said components separated in said first separating column, wherein said second separating column has different separating characteristics than said first separating column;
(c) a collecting volume for collecting said components separated in said first separating column before entering said second separating column said collecting volume being arranged in a flow path between said first and said second separating column, said flow path between said first separating column and said second separating column having a collecting volume receiving space therein for removably and interchangeably receiving the collecting volume in said collecting volume receiving space, said collecting volume having a desired interior size;
(d) a switching assembly for switching said chromatography assembly from a first state, where said components leaving said first separating column are collected in said collecting volume to a second state where said components collected in said collecting volume are transferred to said second separating column; and
(e) a detector for detecting sample components leaving said second separating column:
and wherein
(f) the interior size of said collecting volume is variable by selecting the collecting volume of the desired interior size to be received in the collecting volume receiving space for a particular multi-dimensional chromatography analysis.
13. chromatography assembly for carrying out a multi-dimensional chromatography analysis of a sample, comprising
(a) a first separating column for separating said sample flowing through said separating column into components;
(b) a second separating column for further separating said components separated in said first separating column, wherein said second separating column has different separating characteristics than said first separating column;
(c) a collecting volume module for collecting said components separated in said first separating column before entering said second separating column said collecting volume module being arranged in a flow path between said first and said second separating column, said flow path between said first separating column and said second separating column having a collecting volume module receiving space therein for removably and interchangeably receiving the collecting volume module in said collecting volume module receiving space, said selected collecting volume module having a desired interior size;
(d) a switching assembly for switching said chromatography assembly from a first state, where said components leaving said first separating column are collected in said collecting volume to a second state where said components collected in said collecting volume are transferred to said second separating column; and
(e) a detector for detecting sample components leaving said second separating column:
and wherein
(f) the interior size of said collecting volume is variable by selecting the collecting volume module of the desired interior size to be received in the collecting volume module receiving space for a particular multi-dimensional chromatography analysis.
2. chromatography assembly according to
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15. chromatography assembly according to
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The invention relates to a chromatography assembly and a method for multi-dimensional chromatography.
One such chromatography assembly for multi-dimensional chromatography comprises:
One such method for generating a multi-dimensional chromatogram comprises the steps of:
Such assemblies are known as multi-dimensional or comprehensive chromatography assemblies. In the field of gas chromatography the assemblies and the method are called “GC×GC” or “GC−GC” and in the field of high-performance liquid chromatography (HPLC) are referred to as “LC×LC”. There are mixed assemblies known, such as GC×LC and LC×GC. The assemblies are characterized in that a sample flows through two different columns having different separating characteristics. Non-resolved peaks from the first separating column can be separated in the second separating column. In such a way a very high resolution is achieved.
Known assemblies are based on one of two different principles: One alternative is to freeze separated components in the first separating column by means of a freezing agent, such as nitrogen and to release them after the collection by heating. The other alternative is to switch the fluid flow through the columns and a collecting volume in such a way that the components are cyclically collected in the collecting volume and transferred to the second separating column afterwards. Thereby the use of an expensive freezing agent is avoided. The present invention relates to the latter assembly and method where states are switched by a suitable flow management.
U.S. Pat. No. 7,383,718 B2 (McCurrey) discloses an assembly with a first and a second separating column which are used to carry out two-dimensional gas chromatography. A “flow modulator” with a valve and a pressure control switches the flows in a desired way. Such an assembly is commercially sold by Agilent Technologies Corp. under the name “Agilent 7890A GC System”. In a first step the components separated in the first separating column are collected in a collecting volume. In a second step the collected components are very quickly transferred to the second separating column for further separation. For this purpose, a carrier gas flow is flowed through the collecting volume during the second step. During the collection such carrier gas flow is bypassed around the collecting volume.
Depending on the flow conditions, the design of the columns, and on the application, too much of the mobile phase leaving the first column may enter the collecting volume. In other words: the collecting volume may become full. In such instance, a portion of the components will already enter the second separating column before the transfer step. This is not desirable. However, a larger collecting volume is generally not desired either, as the transfer to the second column will then last a long time.
Aspects of the invention provide a chromatography assembly and a method of the above mentioned kind which enable higher accuracy and reduced analysis times.
According to one aspect of the invention the volume of the collecting volume is variable. The collecting volume can be, for example, formed by an exchangeable, releasably attached pipe, tube, line, or capillary or by a channel etched into a plate. However, it is also possible that the collecting volume is provided in its own module which is adapted to be exchanged as a whole. A variable collecting volume enables an adaptation to the features of the separating columns and the application conditions. The adaptation is effected in the best case scenario by a collection of up to about 50% of the collecting volume, preferably in the range between 40 and 60%. If the first separating column is designed to have a high fluid flow, it is advantageous to use a large collecting volume. This is also the case with the application of high temperatures causing a higher diffusion where a larger collecting volume is advantageous. However, in order to reduce the transfer time of the sample into the second separating column and thereby the measuring time with small fluid flow in the first separating column, it is advantageous to select a smaller collecting volume. The adaptation of the collecting volume is carried out by selecting a line portion or capillary portion matching the selected application and the first separating column, which may then be, for example, screwed to matching connectors of the assembly. Advantageously, the collecting volume has always a larger inner diameter than the first separating column. The line or capillary portion or the exchangeable module is preferably made of metal when used in gas chromatography, whereas it is preferably made of an inert polymer for use in liquid chromatography.
The assembly is particularly suitable with gas chromatography separating columns or liquid chromatography separating columns or a combination thereof.
In a particularly preferred embodiment of the invention, the collecting volume is adapted to be heated. The second separating column preferably has the same temperature as the first separating column. Alternatively, the separating columns are separately maintained at constant temperature.
In a further modification of the invention, the switching assembly comprises a fluid source having a flow or pressure control for generating a fluid flow and a valve for flowing the fluid flow through the collecting volume in the second state.
In a particularly preferred further modification of the invention, a further collecting volume is provided and the fluid flow is flowed through the first collecting volume in the first state and through the second collecting volume in the second state. With such an assembly the collected components from one collecting volume can be transferred to the second separating column simultaneously with a collection in the other collecting volume. Thereby, no sample components are lost for detection. A further advantage of the use of two collecting volumes is the sample transfer over a longer period of time without increasing the duration of the measurement. The transfer to the second separating column can be effected with smaller volume velocities than with the use of only one collecting volume.
The generation of a multi-dimensional chromatogram according to the present invention is characterized in that the collecting volume is adapted to the characteristics of the columns and to the operation conditions. For the collection of the components the assembly is preferably switched between at least two collecting volumes and the collection is achieved in one collection volume while components collected in the other collecting volumes are transferred to the second column, and vice versa.
A liquid may be used as a carrier and the detection may be achieved by means of mass spectrometry with the method according to the present invention. It is understood, however, that the invention may also be used with gas chromatography in addition to or instead of liquid chromatography (LC×LC) or other methods and detection methods may be used, such as UV detection, diode-array detection (DAD) or flame ionization detection (FID).
For switching between the collecting volumes a controlled fluid flow is preferably used which is alternately flowing through the collecting volumes and the inlet pressure of the fluid flow is adjustable and variable in time. The fluid flow is then kept small in the collecting volume where the components are transferred to the second separating column.
Example embodiments are described below in greater detail with reference to the accompanying drawings.
The separating column 12 has a different stationary phase than the separating column 14. In such a way, non-resolved peaks of different components entering the separating column 14 from the separating column 12 are resolved.
A collecting volume 20 is provided between the first separating column 12 and the second separating column 14. In the present embodiment, the collecting volume 20 is a capillary releaseably screwed to both ends of the separating columns 12 and 14 by means of a multipath screw assembly. The capillary forms an exchangeable module together with the screw assembly. In the field of gas chromatography the module is made of high temperature stable, inert stainless steel. In the field of liquid chromatography the module is made of an inert polymer material.
A carrier fluid source 22 is provided in order to influence the flow in the collecting volume 20. In gas chromatography, the carrier gas comes from the carrier gas fluid source 22, such as, for example, molecular hydrogen. On one side, the carrier gas fluid source 22 is connected to the inlet of the collecting volume 20 at the module through a valve 24. On the other side, the carrier gas source 22 is connected to the outlet of the collecting volume 20 through the valve 24 and thereby with the inlet of the second separating column 14. Depending on the position of the valve 24, the carrier fluid flow is either flowed through the collecting volume 20 or bypasses the collecting volume 20.
The assembly operates as follows: A sample having several components enters the first separating column 12 through the sample inlet 16. The components of the sample are separated as well as possible. From there the components enter the collecting volume 20.
In a first step of the cycle, shown in
In a second step of the cycle, shown in
The first and the second step of the cycle are repeated until the entire sample has flowed through the assembly. The duration of the cycle depends on the application and the measuring conditions. A flow and/or pressure control provided at the fluid source enables control over the volume velocities through the collecting volume 20. The collecting volume 20 in the form of a module is provided with a capillary having a fixed length. The inner diameter of the capillary, however, is chosen in such a way that with the given diameters of the first separating column and the selected duration of the cycle, a collection of the sample of about 50% of the collecting volume is achieved. Thereby, for each kind of sample and each kind of column a premature leaving of the sample during the collecting phase is avoided and still a short measuring time is achieved. If the assembly is operated with a different column, the module is exchanged. For this purpose the connectors connecting the fluid source and the separating columns are released and a different module is inserted.
By way of example,
The carrier gas flow from the carrier gas source 22 flows through the collecting volume during the transfer phase (
The separating columns 12 and 14 and the collecting volume 20 are arranged in an oven 40 which can be controlled up to a temperature of 30° C. In an alternative embodiment, which is not shown, the second separating column 14 is arranged in a separate oven.
The assembly operates as follows: In a first step the fluid flow 134 flows to the inlet of the collecting volume 120. Simultaneously, the separated sample from the first separating column 112 flows to the inlet of the other collecting volume 121. The sample is collected in the collecting volume 121 during this step. The content of the collecting volume 120 is transferred to the second separating column with the fluid flow. This situation is shown in
In order to have the sample leaving the first separating column entering the desired collecting volume a small flow portion 130 of the fluid flow is separated before the inlet of the collecting volume and flows to the other inlet together with the sample flow 132. In
By way of example some typical values of the flow conditions shall be illustrated below. It is understood, however, that this serves for illustration of the way of operation only and that the invention is by no means limited to such values.
The carrier gas source is controlled to a gas flow of 20 ml/min as described in the above embodiment and the gas flow in the first separating column is 1 ml/min. In the step shown in
The effects of changing the collecting volume are shown in
If the transfer to the second separating column 114 shall be effected more slowly, the carrier gas flow is reduced by the corresponding collecting volume. This can be done by a flow or pressure control varying in time or by a bypass.
The flow flows from the first separating column 212 with a volume velocity of about 4.81 mm3/s through the switching valve 224 to the collecting volume 221. The volume velocity is there reduced to 0.57 mm3/s due to the larger cross section. The sample in the collecting volume 220 is transferred to the separating column 214 with a volume velocity of 3.2 mm3/s. Such an assembly is particularly suitable for MS-detectors.
Whereas the invention is here illustrated and described with reference to example embodiments thereof presently contemplated as the best mode of carrying out the invention in actual practice, it is to be understood that various changes may be made in adapting the invention to different embodiments without departing from the broader inventive concepts disclosed herein and comprehended by the claims that follow.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5522988, | Jan 25 1985 | The Dow Chemical Company | On-line coupled liquid and gas chromatography system with an interface capillary tube interposed between a pair of capillary chromatographic columns |
7383718, | Feb 21 2006 | Agilent Technologies, Inc. | Single stage flow modulator for performing comprehensive chromatography |
7518103, | Jul 06 2006 | Pulsed flow modulation gas chromatography mass spectrometry with supersonic molecular beams method and apparatus | |
20040093933, | |||
20040182134, | |||
20050218055, | |||
20070214866, | |||
20100101411, | |||
WO2009154984, |
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